Method and apparatus for regulating the pressure in a turbocharged internal combustion engine intake duct

ABSTRACT

A method and apparatus regulates the pressure in the intake duct of a turbocharged internal combustion engine. The internal combustion engine has a control unit, in which a desired pressure value is determined. The current pressure in the intake duct is adjusted to the desired value by a valve device, and the valve device is acted upon by an actuating signal from the control unit. In order to build up the pressure in the intake duct with a suitable dynamic response for each load state, particularly when using a number of valve devices, the actuating signal is used as a control signal, as a function of a relative desired pressure valve, from a control characteristic map stored in the control unit. A controller signal produced in a controller is superimposed on the control signal if required.

BACKGROUND AND SUMMARY OF THE INVENTION

This application claims the priority of DE 196 20 778.9, the disclosure of which is expressly incorporated by reference herein.

The present invention relates to a method for regulating the pressure in the intake duct of an internal combustion engine having an exhaust turbocharger and a control unit configured to determine a desired pressure value as a function of the current load, comprising the steps of setting current pressure in the intake duct via a valve to the desired pressure value to be set, and actuating the valve as a function of an actuating signal produced by the control unit. The present invention also relates to an apparatus for carrying out the foregoing method, which has a throttle valve in the intake duct, an exhaust turbocharger arranged in an exhaust line, a bypass valve, a bypass conduit arranged to be shut off by the bypass valve and to bypass the turbocharger, and a control unit configured to effect a load-dependent setting of the throttle valve and the bypass valve.

DE 39 39 754 A1 describes an internal combustion engine with an exhaust turbocharger having a turbine driven by the stream of exhaust gas and driving a compressor in the intake duct. The turbine in the exhaust line is bypassed by a bypass conduit, which can be shut off by a bypass valve. The regulation of the intake duct pressure to a specified desired pressure value is accomplished by adjusting a throttle valve in the intake duct and by actuating the bypass valve. Thereby, the stream of exhaust gas fed to the turbine of the exhaust turbocharger can be adjusted. The position of the throttle valve and of the bypass valve is determined by a control unit as a function of the load state of the internal combustion engine. For this purpose, actuating signals for actuating drives assigned to the throttle valve and the bypass valve are produced in a control unit. In order to adjust the pressure in the intake duct to the intended desired value, the throttle valve is first of all pivoted in the direction of complete opening of the intake duct in the low-load range of the internal combustion engine. If a further pressure rise in the intake duct is required even after the maximum throttle-valve open position has been reached, the bypass valve is moved as a function of the load by the control unit from its open position up to that time into its closed position. As the load increases, the bypass conduit is therefore shut off, so that an increasing stream of exhaust gas impinges on the turbocharger. This allows a higher desired pressure to be achieved in the intake duct.

Depending on the load state of the internal combustion engine, the controller implemented in the control unit acts upon either the throttle-valve position or the position of the bypass valve. In the transitional range from part load to full load of the internal combustion engine, only a limited dynamic response of the pressure build-up in the intake duct can thereby be achieved. The sequential actuation of the throttle valve and the bypass valve, owing to the common controller for both valve devices, results in an unavoidable regulation delay. Because of the intrinsic dynamic response of the throttle valve and the bypass valve, there is a delay upon each transition of the actuation of one of the two valve devices. It is furthermore disadvantageous that the controller can only be set in an optimum manner for one of the two valve devices. Consequently, optimum regulation of the other valve is impossible.

An object of the present invention is to provide a method and an apparatus for building up the pressure in the intake duct of an internal combustion engine with a suitable dynamic response for each load state, particularly when using a number of valve devices.

According to the invention, this object has been achieved with a method in which the actuating signal is taken as a control signal, as a function of a corrected relative desired pressure value, from a control characteristic map stored in the control unit. When required, a controller signal produced in a controller, in which one input variable is a signal formed from adding the current pressure and the desired value to be set, is superimposed on the control signal. The apparatus for carrying out the foregoing method has a desired-value transmitter and a controller unit, the latter having a switching-signal transmitter, a switching element, a memory with respective control characteristic maps for the throttle valve and the bypass valve and respective controllers, each of which is independently activatable as a function of predetermined switching criteria by the switching-signal transmitter and the switching element.

According to the method of the present invention, adjustment of the pressure in the intake duct is performed by control with superimposed regulation. The actuating signal is made up of a control signal, which is taken from a control characteristic map as a function of a corrected desired pressure value, and of a controller signal, which is superimposed on the control signal as required, in order to achieve exact setting of the pressure to the intended desired value. The permanently active controller ensures that the valve device is supplied continuously with an actuating signal and there are thus no delays due to a dynamic response of the valve device. The control signal can be matched specifically to the dynamic response of the valve device. The superimposed regulation which is switched in as required ensures that the specified desired pressure value can be set exactly and without steady-state error.

A second valve device can be provided for regulating the intake pressure. A second actuating signal independent of the first actuating signal is advantageously produced by the control unit and is taken from a second control characteristic map tailored to the second valve device. This second control signal can, in turn, have a dedicated controller signal superimposed thereon, with the controller signal being produced in a second controller. The controller signals of the first and the second controllers are completely independent and it is advantageous, depending on the load applied, for only one of the two controllers to be activated. One of the two controllers can be activated by a switching signal dependent on the specified desired pressure value. The first controller is preferably assigned to the part-load range and the second controller to the full-load range.

Each of the two controllers is assigned a control characteristic map with a control signal taken from it which acts continuously on the valve devices. Consequently, both valve devices can be operated independently of one another in the transitional range between part load and full load. This provides a favorable dynamic pressure build-up in the intake duct. Also, the separate regulation allows determination of the regulation parameters in a manner matched to the respective valve device.

The calculation of the desired pressure value preferably includes characteristics such as the engine speed and the power demand by the driver. These variables characterize the load state of the internal combustion engine. Ambient conditions such as the ambient air pressure, the temperature of the intake air and the temperature of the cooling water can be included as further influencing variables. All the influencing variables can be defined in the form of characteristic maps, and a plurality of characteristic maps can be provided for each influencing variable. These maps are assigned to the various load ranges of the internal combustion engine. The respective characteristic map is activated by a switching signal which reflects the load state of the internal combustion engine. A PI controller signal is advantageous in this regard because there is no remaining steady-state system error.

The desired pressure value is fed to a switching-signal transmitter in which a hysteresis curve is implemented as a switching curve for the load-dependent activation of one of the two controllers. The hysteresis curve lies between a lower and an upper pressure limit value. A switched change between the controllers takes place when the desired pressure value reaches one of the two limit values.

As an additional condition, a switched change can also take place when the controller signal either of the first or second controller exceeds or undershoots a specified controller limit value. This additional switching condition ensures that the desired intake-pipe pressure is achieved in all cases, even if individual engine components are not operating correctly, as a result of, for example, soiling or contamination. The additional switching condition ensures that a switch is made to the controller for the higher load range in time to reach the desired pressure, even if this is not necessary according to the switching curve stored in the switching-signal transmitter.

The apparatus for carrying out the above-described method includes a throttle valve in the intake duct as the first valve device and a bypass valve in the bypass conduit which bypasses the turbocharger as the further valve device. The control unit which supplies the actuating signals for the regulation of the throttle valve and the bypass valve includes a desired-value transmitter for determining the desired pressure value and a controller unit. The controller unit comprises a memory with respective control characteristic maps for the throttle valve and the bypass valve, and respective controllers. The controllers can be activated by a switching-signal transmitter and a switching element which are likewise part of the controller unit.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects, advantages and novel features of the present invention will become apparent from the following detailed description of the invention when considered in conjunction with the accompanying drawings:

FIG. 1 is a schematic diagram of an internal combustion engine with an exhaust turbocharger and two valve devices to be regulated by a control unit in accordance with the present invention;

FIG. 2 is a flow diagram relating to the calculation of the desired pressure value;

FIG. 3 is a flow diagram relating to the calculation of the actuating variables for each valve device; and

FIG. 4 is a schematic diagram of the switching conditions for switching between the controllers.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an internal combustion engine 1 which is embodied as a diesel internal combustion engine. The internal combustion engine 1 is supplied with combustion air via the intake duct 2. An exhaust turbocharger 4 has turbine 5 arranged in the engine exhaust line 3 and operated by the exhaust gases. The turbine 5 drives a compressor 6 of the turbocharger which is arranged in the intake duct 2 upstream of a first valve device 20. In the illustrated embodiment, the valve device 20 is a throttle valve DK which, to achieve a desired intake pressure in the intake duct 2, is pivoted by an actuator 18 into the required position.

A bypass conduit 7 is provided in the exhaust line 3 to bypass the turbine 5 of the turbocharger 4, branches off from the exhaust line 3 upstream of the turbine 5 and opens into the exhaust line again downstream of the turbine 5. The bypass conduit 7 can be shut off by a second valve device 21 which can be in the form of a bypass valve BV or the like. The bypass valve BV can be pivoted by an actuator 19 between an open position, in which the cross-section of the bypass conduit 7 is completely open, and a closed position, in which the bypass conduit is completely shut off. In the closed position of the bypass valve BV, the entire stream of exhaust gas is passed through the turbine 5 of the turbocharger 4 to thereby develop maximum turbocharger power. The closed position of the bypass valve BV is therefore assigned to the high-load range or full-load range of the internal combustion engine whereas, in the open position of the bypass valve BV, the internal combustion engine 1 is in the low-load range.

A control unit designated generally by numeral 8 comprises a desired-value transmitter 9 for determining the desired pressure value and a controller unit 10 which, in the event of a deviation of the current pressure P2_(ist) in the intake duct 2 from the specified desired value P2_(soll), supplies an actuating voltage U_(DK) or U_(BV) to the actuator 18 or 19 of the throttle valve DK or bypass valve BV.

The input variables of the desired-value transmitter 9 of the control unit 8 are a power demand M_(eW) of the driver, which is proportional to the current load state of the internal combustion engine, and the current engine speed N. As output variables, the desired-value transmitter 9 supplies an (absolute) desired pressure value P2_(soll) to be set and a relative desired pressure value P2_(RK). The influence of the ambient air pressure P_(atm), the temperature T_(L) of the intake air and the temperature T_(W) of the engine coolant are taken into account for the purpose of correcting the desired pressure value.

The absolute and the relative desired pressure values are fed to the controller unit 10, in which a comparison is made between the desired pressure value and the current pressure value P2_(ist). The current pressure P2_(ist) is recorded by a sensor 42 in the intake duct 2 and fed to the controller unit 10 via a measuring line 43. As its output, the controller unit 10 supplies the actuating voltages U_(DK) and U_(BV), which are fed via further measuring lines 44, 45 to the corresponding actuators 18, 19.

The flow diagram of FIG. 2 shows determination of the desired pressure values in the desired-value transmitter 9 of the control unit 8. The power demand M_(eW) of the driver and the current speed N of the internal combustion engine are read in and transformed by a first characteristic map 22 into a desired-pressure base value P2₀. A relative desired-pressure base value P2_(RO) is produced in a summer 32 by subtraction of a settable reference pressure P_(ref) which is preferably 1000 mbar.

In order to be able to include the influence of ambient conditions, the relative desired-pressure base value P2_(R0) is subjected in series-connected multipliers 37, 38, 39 to correction factors which reproduce the influence of ambient conditions such as ambient air pressure P_(atm), temperature T_(L) of the intake air and temperature T_(W) of the engine coolant. In addition, a distinction can be drawn for each influencing variable as to whether the internal combustion engine is in the part-load range or in the full-load range. For this purpose, a comparison element 33 with a two-point characteristic is provided which, depending on the magnitude of the relative desired-pressure base value P2_(R0), supplies an output signal S which represents the current load state of the internal combustion engine. If the relative desired-pressure base value P2_(R0) <0 (part-load range, control is to take place by way of the throttle valve DK), the comparison element 33 supplies a value equal to zero for S. For P2_(R0) ≧0 (full-load range, pressure regulation by way of bypass valve BV), the switching signal S is thus 1.

The switching signal S is fed to the series-connected switching elements 34, 35, 36, and, for S=1, activate the characteristic maps 23a, 24a, 25a, assigned to the bypass valve BV, for the ambient characteristic variables P_(atm), T_(L), T_(W) and, for S=0, correspondingly activates the characteristic maps 23b, 24b, 25b assigned to the throttle valve. After multiplication of the ambient characteristic variables by the relative desired-pressure base value P2_(R0), the obtained corrected relative desired pressure value P2_(RK) is picked up and fed to the controller unit.

To determine the absolute desired pressure value, the corrected relative desired pressure value P2_(RK) is additionally subjected in a summer 40 to the current ambient air pressure P_(atm), from which the corrected absolute desired value P2_(K) is obtained. In a subsequent comparison element 41, the absolute desired value P2_(K) is limited by a minimum-value function to a maximum P2 limit value. Adaptation as a function of the ambient air pressure P_(atm) and the current engine speed N takes place by way of an additional characteristic map 26. The limitation of the P2 limit value by the minimum-value function serves to protect the turbocharger from overspeeds at relatively high altitudes. As an output variable following the comparison element 41, the desired pressure value P2_(soll) to be set is then obtained.

The flow diagram of FIG. 3 shows how the actuating signals in the controller unit 10 of the control unit 8 are determined. The desired pressure values P2_(soll), P2_(RK) supplied by the desired-value transmitter are fed to the controller unit 10 as input variables and processed therein.

The corrected relative desired pressure value P₂ RK is fed as an input variable to the parallel-connected control characteristic maps 11, 13 of the throttle valve and the bypass valve. The control characteristic maps 11, 13 supply a control signal TV_(SDK) or TV_(SBV) as the output variable. As a further input variable, the current engine speed N is taken into account in the determination of the control signals.

The control characteristic maps 11, 13 are active for the entire operation of the internal combustion engine and supply the control signals TV_(SDK) and TV_(SBV) (duty ratio) irrespective of whether the control system is switched on or off. Both the throttle valve and the bypass valve are supplied continuously with control signals. Consequently, there are no problems such as, for example, delays owing to the intrinsic dynamic response of the throttle valve and the bypass valve.

The absolute desired-pressure value P2_(soll) is fed to a summer 28, in which the system deviation dP2 is formed by subtraction of the current pressure P2_(ist). The system deviation dP2, which represents the deviation of the actual pressure P2_(ist) from the specified desired pressure P2_(soll), is fed as an input variable to a first controller 12 for the throttle valve and a parallel-connected second controller 14 for the bypass valve. In the illustrated embodiment, the controllers 12, 14 are PI controllers. The constants of the proportional component and of the integral component are each matched to the dynamic response of the throttle valve and the bypass valve.

The controllers 12, 14 of the throttle valve and the bypass valve, respectively, supply a respective controller signal TV_(RDK) and TV_(RBV) which is then fed to a respective summer 29, 30. In the summer 29, the throttle-valve actuating signal TV_(DK) is formed by summation of the control signal TV_(SDK) and the controller signal TV_(RDK). The bypass-valve control signal TV_(BV) is accordingly formed in the summer 30 by summation of the control signal TV_(SBV) and the controller signal TV_(RBV).

The summers 29, 30 are each arranged upstream of a multiplier 31, 32, in which the actuating signals TV_(DK) and TV_(BV), respectively, are multiplied by a battery voltage U_(Batt). From the multipliers 31, 32, the corresponding output variables are fed to output stages 46, 47, in which, as a function of the actuating signals TV_(DK) and TV_(BV). An actuating voltage U_(DK) and U_(BV), respectively, is produced in the output stages 46, 47 as a function of the actuating signals TV_(DK) and TV_(BV) which, as described with reference to FIG. 1, is passed to the actuators 18, 19 for the throttle valve DK and the bypass valve BV, respectively.

One, but not both simultaneously, of the controllers 12 or 14 is actuated, depending on the load state of the internal combustion engine. The decision as to which controller is activated or which controller signals are connected through to the respective summer is taken in a switching-signal transmitter 15, to which the relative desired-pressure value P2_(RK) is fed as an input variable. The magnitude of the relative desired-pressure value P2_(RK) is used as a decision criterion to determine the current load state the internal combustion engine. In the part-load range, the controller 12 for the throttle valve is activated and, in the full-load range, the controller 14 for the bypass valve is activated.

The switching curve of the switching-signal transmitter 15 is implemented in the form of a hysteresis curve which lies between a predetermined lower pressure limit value P_(T0) and an upper pressure limit value P_(T1). The switching signal T is an output variable of the switchingsignal transmitter 15 and can assume either the value 0 or the value 1. The controller signals of the throttle valve are switched through in the case of the value 0 (throttling), and the controller signals of the bypass valve are switched through in the case of the value 1 (turbocharging). A switched change from one controller to the other takes place whenever the relative desired-pressure value P2_(RK) reaches one of the limit values P_(T0) or P_(T1).

Immediately after the starting of the internal combustion engine, the internal combustion engine is in the part-mode range, i.e. switching signal T=0. At that point, P2_(RK) assumes a value which is less than the upper limit value P_(T1) of the switching curve. With increasing load and increasing engine speed, the relative desired-pressure value P2_(RK) also increases. As soon as the upper pressure limit value P_(T1) is reached, the switching signal switches from T=0 to T=1 whereby the internal combustion engine is now in full-load range in which regulation for the bypass valve is activated.

If the load is now reduced, the relative desired-pressure value P2_(RK) is also reduced. When the lower limit value P_(T0) is reached, the switching signal again switches to the value T=0 whereby the machine is in the part-load range in which throttle-valve regulation is active.

In addition to the switched change dependent on the desired-pressure value P2_(RK), it is advantageous to take into account further switching conditions such as a switched change from the throttle-valve controller 12 to the bypass-valve controller 14 taking place whenever the controller signal TV_(RDK) supplied by the throttle-valve controller 12 exceeds a predetermined controller limit value TV_(DKO). Conversely, there is a switched change from the bypass-valve controller 14 to the throttle-valve controller 12 whenever the controller signal TV_(RBV) supplied by the bypass controller 14 undershoots a predetermined controller limit value TV_(BVU). The controller limit values TV_(DKO), TV_(BVU) are expediently of the same magnitude and are provided with opposite signs.

The switching diagram illustrated in FIG. 4 illustrates this additional switching condition. T=0 represents the throttle-valve controller 12 being activated, and T=1 represents the bypass-valve controller 14 being activated. Immediately after starting, the internal combustion engine is in switching state A, in which the desired-pressure value P2_(RK) is less than the upper pressure limit value P_(T1) and the switching signal T=0. As the primary switching condition, the magnitude of the desired-pressure value P2_(RK) is used. As described, a switched change to T=1, from A to B; takes place as soon as the desired-pressure value P2_(RK) exceeds the upper pressure limit value P_(T1). Conversely, a switched change from B to A, i.e. from bypass-valve regulation to throttle-valve regulation takes place as soon as the relative desired-pressure value P2_(RK) undershoots the lower pressure limit value P_(T0).

Superimposed on this primary switching condition is a further switching condition in which a switched change from T=0 to T=1 is possible even when, although the relative desired-pressure value P2_(RK) has not yet reached the upper pressure limit value P_(T1), the controller signal TV_(RDK) of the throttle valve is above the controller limit value TV_(DKO). A switched change from A to C takes place, in which the switching signal is at T=1 even though the relative desired-pressure value P2_(RK) is less than the upper pressure limit value P_(T1).

If the desired-pressure value P2_(RK) now exceeds the upper pressure limit value P_(T1) the switching state changes from C to B, although no change in the switching signal T is associated therewith. A change from switching state C to A can take place if the bypass-valve controller 14 activated in switching state C supplies a controller signal TV_(RBV) which is below the predetermined limit value TV_(BVU).

From switching stage B (bypass-valve controller active), switching stage D (throttle-valve controller active) can be reached even though the desired-pressure value P2_(RK) is above the lower pressure limit value P_(T0). The switched change from B to D takes place as soon as the controller signal TV_(RBV) of the bypass-valve controller is below the corresponding controller limit value TV_(BVU). Conversely, a change from switching state-D to switching state B can occur if the throttle-valve controller activated in switching state D supplies a controller signal RV_(RDK) which is above the controller limit value TV_(DKO).

From switching state D, a direct change to A can also occur if the desired-pressure value P2_(RK) falls below the lower pressure limit value P_(T0). A switching-signal change and associated change of controller does not, however, take place.

The introduction of the additional switching condition ensures that a controller switchover takes place even when the intake system or the turbocharger is out of tune owing, for example, to dirt or soiling. By way of example, given an ambient air pressure P_(atm) =1000 mbar and a specified desired pressure value P2_(soll) =970 mbar, the relative desired pressure value assumes a value of -30 mbar (without influence of ambient conditions). Owing to the negative value (P2_(RK) less than P_(T1)), the throttle-valve controller is activated. With a current intake pressure P2_(ist) =950 mbar as may be caused, for example, by a dirty air filter, the system error dP2=+20 mbar. The system error cannot be compensated here for by the throttle valve. A switchover to the bypass-valve controller must take place even though the relative desired pressure value P2_(RK) has not yet reached the upper limit value P_(T1). The switchover to the bypass-valve controller is effected by a transition from switching stage A to switching stage C when the controller signal of the throttle-valve controller exceeds the limit value TV_(DKO).

According to FIG. 3, the switching signal T is fed to a switching element 16 associated with the throttle valve and to a switching element 17 associated with the bypass valve. The throttle-valve switching element 16 is arranged directly after the controller 12 and, for T=0, feeds the controller signal TV_(RDK) to the summer 29 arranged on the output side of the switching element 16. Otherwise, the switching element 16 supplies a value 0 for T=1 instead of the controller signal TV_(RDK), so that in this instance the actuating signal TV_(DK) is identical with the control signal TV_(SDK).

Similarly, the switching element 17 arranged between the bypass-valve controller 14 and the summer 30 feeds the controller signals TV_(RBV) to the summer 30 in the event of a switching signal T=1. For T=0, the switching element 17 feeds the value 0 to the summer 30, so that the actuating signal TV_(BV) is identical with the control signal TV_(SBV).

The switching signal T is also fed directly to the controllers 12, 14 in order to reinitialize the respectively activated controller following a switched change and thereby to avoid unwanted jumps in the controller signal. For this, it is necessary that the controller signal TV_(RDK) or TV_(RBV) assume the value 0 at the instant of switching on. This is achieved by the integral component of the controller being made equivalent to the negative proportional component of the same controller.

The actuating signals TV_(DK) of the throttle valve and TV_(BV) of the bypass valve are multiplied in respective multipliers 31, 32 by the battery voltage U_(batt) which can be corrected by a characteristic 27 to compensate for differences in the voltage supply. In respective output stages 46, 47 arranged on the output side, the signals are transformed into the final actuating voltages U_(DK) and U_(BV), respectively, which, as shown in FIG. 1, act upon the actuators 18, 19 for the respective throttle valve DK and the bypass valve BV.

All of the characteristics or characteristic maps of the desired-value transmitter 9 and of the controller unit 10 are advantageously stored as data values in a memory. The data obtained from measurements and experience can be matched individually to each valve device. It is furthermore within the contemplation of the present invention to specify a mathematical function, instead of stored data values, to supply a precise initial value for each input value.

Instead of the two valve devices described above, other valve devices can also be provided. Thereby the intake pressure P2 can be adjusted. Each valve device is assigned a control characteristic map and a controller. It is also within the scope of the present invention to provide just one valve device, for example only the throttle valve or only the bypass valve and, accordingly, to provide just one control characteristic map with a superimposed controller.

If required, the comparison element 33 can be incorporated in the desired-value transmitter 9 and the switching-signal transmitter 15 can be incorporated in the controller unit 10 in order to produce a uniform switching signal for the determination of the load state of the internal combustion engine. It is also contemplated to use a PID controller or some other suitable type of controller instead of a PI controller.

The apparatus according to the invention can also be used with Otto internal combustion engines as well as diesel engines.

Although the invention has been described and illustrated in detail, it is to be clearly understood that the same is by way of illustration and example, and is not to be taken by way of limitation. The spirit and scope of the present invention are to be limited only by the terms of the appended claims. 

What is claimed is:
 1. Method for controlling pressure in an intake pipe of an internal combustion engine having an exhaust turbo charger and a control unit configured to determine a desired pressure value as a function of the current load, comprising the steps of setting current pressure in the intake duct via a valve to a desired pressure value to be set, taking an actuating signal as a control signal, as a function of a corrected relative desired pressure value, from a control characteristic map stored in the control unit, and, upon demand, superimposing on the control signal a controller signal produced in a controller in which one input variable is a signal based upon the current pressure and the desired pressure value to be set, and actuating the valve as a function of an actuating signal produced by the control unit wherein a switching signal for switching the controller on or off is produced in a switching-signal transmitter when a limit value for the corrected relative desired pressure value is exceeded or undershot.
 2. Method according to claim 1, wherein the speed of the internal combustion engine, the power demand of the driver and the influence of ambient conditions including ambient air pressure, intake air temperature and engine coolant temperature are included in the determination of the corrected relative desired pressure value.
 3. Method according to claim 2, wherein a relative base value is produced from an intake-pipe base pressure value by subtracting a reference pressure.
 4. Method according to claim 3, wherein the desired pressure value to be set is determined as a function of the ambient air pressure and the engine speed and is limited to a maximum value by a minimum-value function.
 5. Method according to claim 2, wherein the characteristic variables which determine the desired pressure values are characteristic maps.
 6. Method according to claim 1, wherein a second valve device for pressure regulation is acted upon by an actuating signal which includes the control signal of a second control characteristic map.
 7. Method according to claim 6, further comprising the step of producing a second controller signal by a second controller for the second valve and superimposing the second controller signal on the control signal, and using a switching signal produced in a switching-signal transmitter to activate only the first controller of the first valve device or only the second controller of the second valve device but not both.
 8. Method according to claim 7, further comprising the step of supplying, via the activated controller an initial controller signal with the initial value 0 in the event of a change, an integral component of the activated controller being set so as to be equal to a negative proportional component.
 9. Method according to claim 8, wherein the first controller is assigned to the high-load range and the second controller is assigned to the low-load range of the internal combustion engine.
 10. Method according to claim 7, wherein the switching curve of the switching-signal transmitter is a hysteresis curve which lies between a specified lower pressure limit value and an upper pressure limit value, with a switched change taking place when a relative corrected desired pressure value reaches one of the limit values.
 11. Method according to claim 7, wherein a switched change takes place when the controller signal supplied by the first or second controller is other than a specified controller limit value.
 12. Method according to claim 6, wherein characteristic maps for the influence of the ambient conditions are assigned to the two valves to determine the corrected relative desired pressure value, and are driven as a function of a switching signal representative of the load state of the internal combustion engine.
 13. Method according to claim 12, wherein the load-representative signal is determined by a relative desired-pressure value.
 14. Method according to claim 6, further comprising the step of multiplying the actuating signals for each valve device by a value corresponding to the battery voltage.
 15. Method according to claim 14, further comprising the step of correcting with a characteristic a value corresponding to the battery voltage to compensate for voltage differences. 